Factors Affecting Triple Staining of Human Sperm

We have previously described a triple stain for evaluating normal acrosome reactions of human sperm. This procedure uses trypan blue to distinguish live and dead sperm, Bismarck brown to stain the sperm's postacrosomal region, and rose Bengal to stain the sperm's acrosome. We have recently found that batches of rose Bengal vary significantly in their ability to produce good staining of the acrosome in this procedure. This appears to be due to variations in the intrinsic pH of rose Bengal solutions and the presence of nondye contaminants in the stain. In this study, we have evaluated acrosomal staining using 6 batches of rose Bengal and report a method for achieving uniform staining quality with each batch. Solutions of rose Bengal (0.8%) are made up in 0.1 M Tris HC1 (pH 2.3) buffer and adjusted to pH 5.3 if necessary. For most batches of rose Bengal this promotes precipitation of some of the dye and an unidentified contaminating crystal. The precipitate is removed by centrifugation, and the supernatants have been found to give good to excellent staining of the acrosomes for all batches tested. Solutions of both rose Bengal and Bismarck brown are stable for at least 5 days but their pH values should be monitored daily and adjusted to 5.3 and 1.8 respectively if drifting occurs. We have also observed some variation in the intensity of rose Bengal staining of the acrosome from donor to donor and recommend that staining times in rose Bengal be adjusted for each donor.     

Use of triple stain technique for simultaneous assessment of vitality and acrosomal status in boar spermatozoa

The object of this study was to adapt the triple stain technique to diluted and incubated boar spermatozoa. Freshly ejaculated semen was resuspended in MR-A diluent to contain 3x10(7) cells/ml (diluted spermatozoa) and was subsequently capacitated (incubated spermatozoa). Experiments were conducted to show the conditions required for optimal staining quality and validation of triple stain technique. The most satisfactory staining solutions for diluted spermatozoa were 2% Trypan blue at 37 degrees C for 15 minutes, 0.8% Bismarck brown in 30% ethyl alcohol (pH 2.8) at 40 degrees C for 10 minutes and 0.8% rose Bengal in 0.1 M of Tris (pH 4.3) at 21 degrees C for 20 minutes. Satisfactory results were obtained for incubated spermatozoa with rose Bengal when the staining time was 10 minutes. Triple stain technique seemed to be a useful method for the simultaneous assessment of sperm vitality and acrosomal status; consequently, it should be valuable tool, for use in porcine in vitro fertilization systems.     

Displacement

Displacement is a noncommital term for the reactions that occur when slides previously stained in phloxine or rose Bengal are immersed for varying lengths of time in a solution of another dye in ethyl Cellosolve. In most histotechnic tests Lendrum's (1947) phloxine-tartrazine is given as the stain for acidophilic inclusion bodies. However the lack of contrast between the phloxine and tartrazine has been a serious limitation. A number of dyes were tried as possible substitutes for the tartrazine. A rose Bengal-Bismark brown Y procedure was developed which stains similarly to Lendrum's phloxine-tartrazine and which doer have the needed contrast. After staining for 10 min in 1% aqueous rose Bengal and rinsing in isopropyl alcohol slides are placed for 20, 30, 40 and 50 min in 0.05% Bismark brown Y in ethyl Cellosolve. In various tissues and structures the rose Bengal is sequentially displaced by the Bismark brown Y. Thus collagen loses the red stain after 30 min while acidophilic structures like sperm heads and Paneth cell granules retain the red stain after 50 min in the displacement solution. The results are strikingly similar to staining with alkaline Biebrich scarlet.     

Displacement.

Displacement is a noncommital term for the reactions that occur when slides previously stained in phloxine or rose Bengal are immersed for varying lengths of time in a solution of another dye in ethyl Cellosolve. In most histotechnic texts Lendrum's (1947) phloxine-tartrazine is given as the stain for acidophilic inclusion bodies. However the lack between the phloxine and tartrazine has been a serious limitation. A number of dyes were tried as possible substitutes for the tartrazine. A rose Bengal-Bismark brown Y procedure was developed which stains similarly to Lendrum's phloxine-tartrazine and which does have the needed contrast. After staining for 10 min in 1% aqueous rose Bengal and rinsing in isopropyl alcohol slides are placed for 20, 30, 40 and 50 min in 0.05% Bismark brown Y in ethyl Cellosolve. In various tissues and structures the rose Bengal is sequentially displaced by the Bismark brown Y. Thus collagen loses the red stain after 30 min while acedophilic structures like sperm heads and Paneth cell granules retain the red stain after 50 min in the displacement solution. The results are strikingly similar to staining with alkaline Biebrich scarlet.     

A triple-stain technique for evaluating normal acrosome reactions of human sperm

A triple-stain technique has been developed to score normal acrosome-reacted human sperm in fixed smears. Live and dead sperm are first differentiated using the vital stain trypan blue. Sperm are then fixed in glutaraldehyde, dried onto slides, and the postacrosomal region and acrosome are differentiated using Bismark brown and Rose Bengal. Slides are examined at 1,000 X with a bright-field microscope and assessed for 1) the percentage of sperm that were alive at the time of fixation and 2) the percentage of sperm that had undergone normal acrosome reactions. Experiments are included that show that trypan blue is a reliable stain for dead sperm and that Rose Bengal stains only sperm having intact acrosomes. This technique may have applications in experimental and clinical studies on sperm capacitation, acrosome reactions, and fertilization in laboratory and domestic animals as well as in man.     

Alkalinization of acrosome measured by GFP as a pH indicator and its relation to sperm capacitation

We previously targeted EGFP (a mutant of green fluorescent protein) to the lumen of the mouse sperm acrosome and reported the time course of EGFP release during the acrosome reaction. In the study reported here, we estimated the pH within the mouse sperm acrosome utilizing the pH-dependent nature of EGFP fluorescence. The average intra-acrosomal pH was estimated to be 5.3 +/- 0.1 immediately after sperm preparation, gradually increasing to 6.2 +/- 0.3 during 120 min of incubation in TYH media suitable for capacitation. Spontaneous acrosome reactions were noted to increase concomitantly with acrosomal alkalinization during incubation. We also demonstrated that acrosomal antigens detected by monoclonal antibodies MN7 and MC41 did not dissolve following the acrosome reaction in pH 5.3 media, but dissolved at pH 6.2. These data suggest that acrosomal alkalinization during incubation conducive for sperm capacitation may function to alter acrosomal contents and prepare them for release during the acrosome reaction.     

Staining procedure to detect viability and the true acrosome reaction in spermatozoa of various species

A simple dual stain procedure (DS) for simultaneously determining sperm viability and acrosomal status is described. The DS includes the use of the vital stain trypan blue to detect live and dead spermatozoa and Giemsa to detect the presence or absence of an acrosome. For staining, spermatozoa are washed, incubated with trypan blue, washed, dried onto slides, and subjected to Giemsa. Dead spermatozoa stain blue in the postacrosomal region while live spermatozoa remain unstained. The acrosome stains light purple–dark pink while acrosome-free sperm remain unstained. This staining pattern enables differentiation of spermatozoa which have undergone a true acrosome reaction (TAR) from those which have undergone a false acrosome reaction (FAR). Incubation of bull, boar, ram, and stallion spermatozoa for 60 minutes at 37°C in the presence of calcium ionophore A23187 increased the proportion of spermatozoa undergoing a TAR in all species except the stallion. Incubation of bull spermatozoa for up to 24 hours at 37°C resulted in a decrease over time in the percentage of live acrosome-intact spermatozoa and a simultaneous increase in the percentage of spermatozoa categorized as having undergone a TAR and FAR. The DS could be a useful technique in evaluating sperm viability and acrosomal status in fertilization and clinical studies.     

Evaluation of sperm acrosome reaction in the Asiatic elephant

This study focuses on the effect of chemicals on acrosome reaction in elephant spermatozoa. Semen was collected at the Washington Park Zoo in Portland, Oregon, from an 11-yr-old Asian elephant by artificial vagina (7 ejaculates) and transported to Mahidol University in Bangkok in extender at 4 to 5 degrees C within 24 to 28 h. A total of 500 x 10(6) sperm/mL was used for the control and for each of the 4 treatment groups: 1) cAMP (0.1 mM); 2) caffeine (0.1 mM); 3) Penicillamine hypotaurine and epinephine, PHE (penicillamine 2 mM, hypotaurine 1 mM, epinephine 1 mM); and 4) heparin (10 microg/mL) at 39 degrees C for 2 h. Aliquots were removed and the sperm viability, abnormal morphology, and acrosome status were evaluated by triple stain technique. Transmission electron microscopy (TEM) was used to observe changes of the sperm head membrane in all treatment groups. Trypan blue reliably stained dead spermatozoa, while rose Bengal stained only the spermatozoa with intact acrosomes. The concentration of dead sperm cells was similar in the 4 groups. The percentages of live acrosome-reacted spermatozoa in the control and in groups treated with caffeine, PHE, cAMP and heparin were 19.5 +/- 4.3, 38.1 +/- 4.0, 34.8 +/- 3.7, 29.8 +/- 0.8 and 28.0 +/- 4.2, respectively. The acrosome reaction rate was higher in the treatment groups than in the control (P<0.05). Caffeine and PHE caused significantly higher acrosome reaction of the sperm head than cAMP or heparin (P<0.05). The electron micrographs showed that the acrosome reaction occurred by the presence of apical vesiculation. The results indicated that 1) the triple stain technique allowed for evaluation of both viability and acrosome reaction simultaneously in elephant spermatozoa,2) acrosome reaction occurred at a high rate in all 3 treatment groups. 3) the effects of caffeine and PHE were significantly higher (P<0.05) than of cAMP and heparin, and 4) the data obtained from the triple stain technique corresponded to those from TEM.     

SpermBlue®: A new universal stain for human and animal sperm which is also amenable to automated sperm morphology analysis

Abstract

Our study was aimed at exploring a simple procedure to stain differentially the acrosome, head, midpiece, and flagellum of human and animal sperm. A further prerequisite was that sperm morphology of the stained samples could be analyzed using automated sperm morphology analysis (ASMA). We developed a new staining process using SpermBlue® fixative and SpermBlue® stain, which are iso-osmotic in relation to semen. The entire fixation and staining processes requires only 25 min. Three main steps are required. First, a routine sperm smear is made by either using semen or sperm in a diluting medium. The smear is allowed to air dry at room temperature. Second, the smear is fixed for 10 min by either placing the slide with the dried smear in a staining tray containing SpermBlue® fixative or by adding 1 ml SpermBlue® fixative to the slide. Third, the fixed smear is stained for 15 min by either immersing the slide in a staining tray containing SpermBlue® stain or adding four drops of SpermBlue® stain to the fixed smear. The stained slide is dipped gently in distilled water followed by air drying and mounting in DPX® or an equivalent medium. The method is simple and suitable for field conditions. Sperm of human, three monkey species, horse, boar, bull, ram, mouse, rat, domestic chicken, fish, and invertebrate species were stained successfully using the SpermBlue® staining process. SpermBlue® stains human and animal sperm different hues or intensities of blue. It is possible to distinguish clearly the acrosome, sperm head, midpiece, principal piece of the tail, and even the short end piece. The Sperm Class Analyzer® ASMA system was used successfully to quantify sperm head and midpiece measurements automatically at either 600 × or 1000 × magnification for most of the species studied.     

Simultaneous evaluation of viability and acrosome integrity of mouse spermatozoa using light microscopy

Determination of the percentage of live cells with intact acrosomes and no morphologic aberrations could be a practical index of semen quality. We applied viability and acrosome staining techniques, originally described for bull, boar and rabbit sperm, to mouse spermatozoa. The viability stain was either trypan blue or Congo red. The stain was precipitated by neutral red in the fixative. The acrosome was stained by Giemsa. Sperm morphology, including cytoplasmic droplets, could be evaluated as well. The staining method described here is a useful routine tool for simultaneous evaluation of the plasma membrane integrity of different sperm subdomains, the status of the acrosome, and cellular morphology.     

Staining of sturgeon spermatozoa with trypsin inhibitor from soybean, Alexa Fluor® 488 conjugate for visualization of sturgeon acrosome

Trypsin-like activity, similar to acrosin, is present in sturgeon spermatozoa and can be a potential target for trypsin inhibitors. The objective of this work was to use a fluorescent soybean trypsin inhibitor (SBTI) conjugate with the Alexa Fluor^® 488 dye for visualization of the sturgeon acrosome. After incubation with SBTI-Alexa, a strong signal was observed both in the acrosome and midpiece or implantation fossa region. We have also found that SBTI-Alexa staining can be combined with PI viability test. Detailed examination of staining pattern revealed that SBTI-Alexa can stain either acrosome or whole sperm. Staining of whole sperm correlated with dead staining ( r ² = 0.94, P < 0.01). However, in fresh semen most cells (93–97%) were not stained with SBTI-Alexa, probably due to intact acrosomes. Further studies should test if SBTI-Alexa can be applied to monitor the acrosome status during the acrosome reaction and cryopreservation.     

Evaluation of acrosomal status of bovine spermatozoa using concanavalin a lectin

We report here that fluorescein isothiocyanate-conjugated concanavalin A (FITC-ConA) specifically labels the acrosomal region of acrosome-reacted bovine spermatozoa. This labeling is found to be useful in evaluating the acrosome status of bovine spermatozoa. When fresh bovine spermatozoa that had been fixed with 4% formaldehyde, smeared on glass slides and then air-dried were stained by FITC-ConA, weak fluorescence was observed on the acrosomal region, although almost all the spermatozoa appeared to be acrosome-intact. However, when fresh sperm suspensions were incubated with FITC-ConA and then mounted on glass slides, no fluorescence was observed on the acrosomal region. Therefore, in the ensuing experiments, both the fixation and the FITC-ConA staining of spermatozoa were done in suspension. When ethanol-treated spermatozoa, whose outer membrane may be permeabilized, were stained with FITC-ConA, the fluorescence was extensively observed on the inner acrosomal region. This fluorescence was inhibited in the presence of 0.2 M D-mannose, a competitive sugar, suggesting that FITC-ConA binds specifically to glycocomponents on the inner acrosomal membrane. We next tried to stain fresh or frozen-thawed spermatozoa from 3 different bulls that had been treated with the calcium ionophore A23187, which is known to induce acrosome reaction of bovine spermatozoa, with FITC-ConA. A significant correlation between the percentage of ConA-labeled spermatozoa and that of rose bengal stained negative ones at various time points during A23187 incubation was achieved. Furthermore, suitability of dual staining to distinguish between physiological acrosome reaction (acrosome-lost and live) and degenerative acrosomal loss (acrosome-lost and dead) using FITC-ConA and Hoechst bis-benzimide 33258 (H258) supravital stain was also confirmed. From these results, it was concluded that the FITC-ConA labeling procedure is a feasible and reliable method for the assessment of physiological acrosome reaction of bovine spermatozoa.     

Identifying non-sperm particles during flow cytometric physiological assessment: a simple approach

Flow cytometry is now being used more frequently to determine sperm functional characteristics during semen assessment for artificial insemination. With this methodology, viable and potentially functional cells are detected as unstained events differentiated from non-sperm events through their light-scattering characteristics. However, it can be shown mathematically that identification of sperm on the basis of light scatter leads to significant overestimation of unstained viable cells and underestimation of responding cells in tests of sperm function (subpopulations expressing different fluorescence patterns). We have developed a simple and cost-efficient flow cytometric approach for identifying non-sperm particles that can be carried out in parallel with functional assessments. Our method is based on the sperm's osmotic intolerance. Diluted in water, lethal osmotic shock causes major damage to the cell membranes, and all sperm will stain with propidium iodide (PI). Particulate material which is not PI-positive can then be quantitatively evaluated by FACS analysis and the results substituted in mathematical equations to provide true values for sperm counts and subpopulations. In practical tests, the percentage of non-sperm particles determined by this technique was closely comparable to the figure obtained either by SYBR14^®/PI staining or by PI/CFDA staining. As well as being valuable with respect to tests of sperm function, the procedure is also suitable for obtaining accurate sperm counts during routine semen evaluation.     

The Use of Bismarck Brown Y in some new Stain Schedules

The staining quality of Bismarck brown Y may be improved and sterility maintained by adding 5% phenol to a 1% aqueous solution. Use the phenolic Bismarck brown in combination with iron alum hematoxylin except for stripped epidermis in the following procedures:

Stem and Root Schedule: Mordant sections from water in 4% iron alum for 10 minutes. Rinse in distilled water and stain in 0.5% aqueous hematoxylin for 1 minute or until darkly stained. Rinse in distilled water and destain in 2% iron alum until a gray color appears. Rinse thoroly in distilled water and intensify hematoxylin by transferring sections to 0.5% aqueous lithium carbonate until the desired black color appears. Rinse thoroly in distilled water and stain for 1-5 minutes in phenolic Bismarck brown. Rinse in distilled water, dehydrate successively in 30, 50, 70, 95 and 100% alcohol. Clear in methyl salicylate for 5 minutes, then to xylene for 3-5 minutes, and mount in balsam.

Middle Lamellae in Wood: Destain more thoroly in 2% iron alum than for the general stem and root schedule, and intensify in lithium carbonate for a longer period (about 1 hour).

White Potato Tuber Sections: Modify above schedule by reducing time of destaining in 2% iron alum to about 30-60 seconds and intensify hematoxylin until starch grains appear bluish in color. Stain in phenolic Bismarck brown for 1-2 minutes.

Wheat Grain Sections: Fix grain for sectioning when in “dough” stage. Use schedule the same as for potato tuber except for reducing time of staining in phenolic Bismarck brown to about 45 seconds.

Tradescantia zebrina Epidermis: Strip epidermis from leaf while submerged in water. Fix in 100% alcohol 10 minutes, pass thru 95, 70, 50, 30, and 10% alcohol to water. Stain in phenolic Bismarck brown for 10-20 minutes. Dehydrate, clear in methyl salicylate and mount in balsam.     

Bismarck Brown As A Stain For Mucoproteins

Bismarck brown has been used for many years as a stain for mucin. But some types of mucoprotein are so water-labile that they cannot be demonstrated by the aqueous or weak alcoholic solutions usually employed. It has been found that Bismarck brown in slightly acidified, strong alcoholic, solution stains mucin. A simple method is given for using this solution for staining water-stable mucoproteins. Another method is included in which full precautions are given for avoidance of water at all stages subsequent to fixation. This method must be used for the more water-labile mucoproteins. By the use of these methods, it has been possible to demonstrate a wide range of mucoproteins including those of the mast cells of Hardie and that of the zona pellucida of the graafian follicle.     

Acrosome reaction induced by immunoaggregation of a proteinase inhibitor bound to the murine sperm head.

ZP3, a glycoprotein of the murine zona pellucida, functions both to bind acrosome intact sperm and to induce the acrosome reaction. Solubilized whole zonae as well as purified ZP3 are able to induce acrosome reactions in capacitated sperm. Pronase digests of whole zonae yield glycopeptides that bind to sperm but are unable to induce acrosome reactions. However, immunoaggregation of these glycopeptides results in the exocytosis of the acrosome in the majority of treated sperm. The data suggest that ZP3 triggers the acrosome reaction by the aggregation of ZP3 binding sites on the sperm head. If aggregation of ZP3 binding sites is important in the induction of the acrosome reaction, then it may be possible to induce the acrosome reaction in the absence of zona by immunoaggregation of the sites. This presentation deals with the immunoaggregation of a proteinase inhibitor of seminal vesicle origin (SVI) that binds to a site on the sperm head known to participate in zona binding. We show that capacitated murine sperm, pretreated with the SVI, will acrosome react, as determined by Coomassie brilliant blue staining, when incubated with rabbit antiinhibitor antiserum (anti-SVI). The percentage of SVI-treated sperm displaying an acrosome reaction is dependent on the concentration of the immune serum. Sperm stain positive for intact acrosomes when anti-SVI Fab fragments or normal rabbit serum is substituted for the immune serum. However, when capacitated sperm, treated with both SVI and anti-SVI Fab fragments, are incubated with goat antirabbit IgG, the majority of sperm acrosome react. The data suggest that the aggregation of SVI bound to the sperm surface, in the absence of zona glycoproteins, is sufficient to induce the acrosome reaction.     

SNARE proteins and caveolin-1 in stallion spermatozoa: possible implications for fertility

Proteins implicated in the "SNARE hypothesis" for membrane fusion have been characterized in the acrosome of several mammalian species, and a functional role for these proteins during the acrosome reaction has been proposed. We have investigated the presence of SNAREs in equine sperm, using semen samples obtained from stallions with varying fertility. Immunocytochemical analysis revealed that members of different SNARE families can be detected on the acrosome of equine sperm, notably in the acrosomal cap and equatorial segment. These proteins include the t-SNARE syntaxin, the v-SNARE synaptobrevin/VAMP, the calcium sensor synaptotagmin, and the ATPase NSF. Also present is caveolin-1, a component of lipid rafts. Stallions with fertility problems presented the worst quality of sperm and acrosomal membrane, and had less sperm cells stained positively for SNAREs and caveolin-1, than sperm from fertile donors (p < 0.001). Ubiquitin surface staining was also performed and it seemed to inversely correlate with stallion fertility, supporting data obtained with the negative staining technique. A male-related problem was confirmed when mares that had failed to impregnate with samples from an infertile stallion were successfully inseminated with sperm from a fertile donor. Furthermore NSF, synaptotagmin and caveolin-1 staining seemed to be useful in predicting stallion fertility, i.e. significantly more sperm cells stained positively for these proteins in samples from fertile males. Although these results need to be expanded on a larger scale, they suggest that acrosomal and surface staining of equine sperm with novel probes may constitute useful tools in predicting stallion fertility.     

Prognostic value of spermatological parameters as predictors of in vitro fertility of frozen-thawed bull semen

Cryopreservation imposes irreversible damage to sperm membranes, such as swelling and disruption of plasma and acrosome membranes, changes in membrane fluidity, altered influx of calcium, and changes in enzyme activity. Morphological integrity of the sperm plasma membrane has been widely studied using different techniques, including exposure of spermatozoa to hypoosmotic solutions (provides information concerning the biochemical activity of the sperm tail membrane), supravital test using eosin stain (yields information regarding sperm head membrane integrity), and Trypan-blue Giemsa stain (TBG; reveals both sperm plasma membrane and acrosome integrity). The objective of this study was to combine these tests in order to provide information about the integrity of the whole sperm surface, as well as acrosome status, and determine if the results of these tests were associated with sperm in vitro fertilizing ability. Stepwise regression analyses yielded a model in which fertility (maintain variable) was expressed as a combination of the results of different spermatological parameters (independent variables). The results of a test combining supravital eosin staining of samples previously submitted to hypoosmotic swelling test (STHOS) accounted for the greatest proportion of variation in fertilization rates (78%). Inclusion of the results of dual staining with TBG increased the proportion of variation in fertility rate that could be accounted for to 82%. Therefore, sperm plasma membrane integrity and function, and acrosome integrity can be considered important variables for normal sperm function and STHOST and TBG could be used for the prognosis of the potential fertility of bovine semen samples used for IVF or AI.     

Phosphotungstic Acid-Eosin Combined with Hematoxylin as A Stain for Negri Bodies in Paraffin Sections

Experimentation with the Papanicolaou stain in this laboratory led to the discovery that the eosin, combined with phosphotungstic acid, was responsible for differential staining of Negri bodies. Eosin prepared as in EA 36 was used, but without the light green and Bismarck brown. Paraffin sections of hippocampus from brains of animal affected with rabies were fixed in 10% formol or in a mixture of 2 volumes of saturated aqueous HgCl₂ and 1 volume of absolute alcohol. They were stained first with hematoxylin and then with eosin. This procedure gave better results than staining with other types of eosin or by the original EA 36 mixture. The Negri bodies were well stained and their structure easily visible. The best results were obtained from material fixed with the HgCl₂ solution.     

Validation of non-fluorescent methods to reliably detect acrosomal and plasma membrane integrity of common marmoset (Callithrix jacchus) sperm

Simple, rapid and stable sperm evaluation methods which have been optimized for common marmoset (Callithrix jacchus) are critical for studies involving collection and evaluation of sperm in the field. This is particularly important for new species groups such as Callitrichidae where the sperm have been little studied. Of this family, C. jacchus is the best known, and has been chosen as a model species for other members of the genus Callithrix. The fundamental evaluation parameters for sperm of any species are viability and acrosomal status. Semen samples were collected by penile vibratory stimulation. To evaluate sperm plasma membrane integrity, Eosin-Nigrosin was tested here for the common marmoset sperm to be used under field conditions. Further, a non-fluorescent stain for acrosome, the "Simple" stain, developed for domestic and wild cats, was tested on common marmoset sperm. This was compared with a fluorescent staining, Fluorescein isothiocyanate-Pisum sativum agglutinin (FITC-PSA), routinely used and validated for common marmoset at the German Primate Centre to evaluate acrosomal integrity. Results obtained with the "Simple" stain showed a marked differentiation between sperm with intact and non-intact acrosome both with and without ionophore treatment and closely correlated with results obtained with FITC-PSA. Temperature had no effect on the results with the "Simple" stain and the complete processing is simple enough to be carried out under field conditions. These findings indicated that the "Simple" stain and Eosin-Nigrosin provide rapid and accurate results for C. jacchus sperm and that those methods can be reliably used as field tools for sperm evaluation for this species.